Dental alignment system and method for dental implant placement

ABSTRACT

A dental alignment guide system for dental implant placement has an anatomical guide, a tooth supported guide and a surgical guide. The system further can have an articulation piece, a prosthetic seat, an analog anatomical model and artificial teeth. The system has a plurality of implants, the implants being abutments, preferably multiunit abutments, a plurality of screws for attaching the anatomical guide to bone, pins to removably attach the various guides and the artificial teeth to the anatomical guide as assemblies during the method of practicing the invention.

RELATED APPLICATIONS

The present invention is a continuation of co-pending U.S. applicationSer. No. 15/913,425 filed on Mar. 06, 2018 entitled, “A Dental AlignmentSystem And Method For Dental Implant Placement”.

TECHNICAL FIELD

An improved dental alignment guide method and system for dental implantplacement is disclosed.

BACKGROUND OF THE INVENTION

A variety of surgical guide devices are being used to assist in theplacement of dental implants.

These guides are commonly divided into three classes, bone bornesurgical drill guides and gum tissue borne surgical guides that are usedin full arch cases and tooth borne guides that are typically used inpartial arch cases. The tooth borne guide works well for smaller archcases requiring two or three implants, but doesn't work well for fullarch cases as the teeth must be removed.

In bone borne guides, the soft gum tissue is removed or at leastdisplaced by flapping to expose the patient's jaw bone. The bone bornesurgical guides is made to fit on the bone and is made from digitaljawbone model or by rapid prototype models made by 3D printing.

Gum tissue borne surgical guides fit directly onto the soft gum tissue.It is a less invasive technique, but it is generally considered inferiorto bone borne guides as the soft tissue is generally unstable and,therefore the ability to maintain alignment and accuracy is sacrificed.

Both of these current forms of guides have drawbacks, one of which isthe bulky size and structure of the guides which occupy a large amountof space in the patient's mouth. Often, the pins and fasteners used tosecure the guide protrude and project into the patient's soft facialtissue. In the prior art the devices rely on seating on the ridge of thebone. this is highly inaccurate due to the inability to determine bonein the area of the ridge and tooth extraction. This area changes duringextraction as well creating more inaccuracy. The present invention nowseats on the facial bone that is much clearer in the CT images. Thisallows the guide to be inserted from the facial direction onto thebuccal or labial bone. The placement of the guide on the buccal bone ismore accurate than previous designs that are pinned 10-15 mm fromimplant placement. The present invention is can be within 2 to 3 mm fromimplant placement.

Another drawback is the time required to prepare large areas of exposedbone on both the labial and the lingual side, in the case of bonesupported guides, wherein the creation of the large flap is painful whenthe patient comes out of sedation and also increases the risk ofinfection. This length of time of surgery is problematic as the patientis under sedation and therefore exposed to higher risk.

The present invention, unlike the prior art devices which have bulkystructures straddling both sides of the jaw bone for support, is greatlyreduced in size and yet is accurately secured to bone.

The present invention provides a system that is extremely accurate andprecise while much quicker and easier to use, thus reducing the time ofthe surgical procedure.

The system of the present invention as described herein provides aplurality of devices that aid the surgeon and allow for an improvedpatient outcome.

SUMMARY OF THE INVENTION

A dental alignment guide system for dental implant placement has ananatomical guide, a tooth supported guide and a surgical guide. Thesystem further can have an articulation piece, a prosthetic seat, ananalog anatomical model and artificial teeth. The system has a pluralityof implants, abutments, preferably multiunit abutments, titaniumcylinders and a plurality of screws for attaching the anatomical guideto bone, pins to removably attach the various guides and the artificialteeth to the anatomical guide as assemblies during the method ofpracticing the invention.

The anatomical guide has an arch shaped structure having a first end anda second end. The arch shaped structure has a curved exterior wall and acurved interior wall extending between the ends. The interior wall isformed to abut against and be secured to a portion of a labial and/orbuccal side of a patient's exposed bone of the alveolar process withsoft gum tissue removed or displaced by flapping. The curved exteriorwall has at least one fastener opening extending through the arch shapedstructure. Each fastener opening is configured to receive a fastener tosecure the anatomical guide to the exposed bone of either the mandibleor the maxilla, preferably the fasteners are threaded screws. The toothsupported guide is made with a “U” shaped curved structure configured tovertically fit onto a patient's existing teeth and connects to theanatomical guide with a latch which includes a connection extending fromthe “U” shaped curved structure to an end. The connection is sized to bereceived and complimentarily fit into a connection aperture on theanatomical guide. The anatomical guide and the tooth supported guidewhen connected together at the latch form an assembly. The assembly ofthe anatomical guide and the tooth supported guide are tooth supportedvertically to align the interior wall of the anatomical guide to abutagainst the exposed bone prior to securing the anatomical guide withfasteners to the exposed bone. Alternatively, the anatomical guide canbe seated against the bone in the correct position based on the anatomy.Then the tooth supported guide can be inserted over the teeth andassembled to the anatomical guide verifying correct placement. Theassembly is configured to pivot or rotate as the tooth supported guideis placed onto the teeth while sliding into place allowing the attachedanatomical guide to pass under the teeth to abut against the exposedbone while being partially under an undercut of the exposed bone andteeth. The connection can be a plurality of support bars extending fromthe “U” shaped curved structure to an end. Each end of the support barsis sized to be received and complimentarily fit into a connectionaperture of the latch on the anatomical guide. At least the ends of thesupport bars of the tooth supported guide in proximity to one of thefirst end and the second end of the anatomical guide have an opening andthe connection aperture of the anatomical guide has a pair of openingsaligned with said support bar end opening on assembly. The alignedopenings are configured to receive a pin or locking device forsupporting and coupling the anatomical guide to the tooth supportedguide. The tooth supported guide has at least one leg support. In oneembodiment the tooth supported guide has three leg supports, a middleleg support interposed between the other two leg supports, the middleleg support can have an end with a round cross section, the other twoleg supports having the ends with either a polygonal cross sectionhaving three or more sides or a circular cross-section or anycombination thereof. The “U” shaped curved structure has a plurality ofapertures on the “U” shaped curved structure, the apertures formingwindows open to verify tooth position. The tooth supported guide has aconnector between each pair of adjacent support bars, the connectorbeing below the “U” shaped curved structure and above the ends of thesupport bars. The tooth supported guide is removably latch to theanatomical guide as the assembly, and the anatomical guide after beingfastened to the exposed bone can have the tooth supported guide removedfrom the assembly. The dental alignment guide system further has atleast one threaded screw to fasten the anatomical guide to the exposedbone. Each of the at least one screw passing through one of the at leastone fastener openings of the anatomical guide. The anatomical guide hasa flat outer surface extending between the curved interior wall and thecurved exterior wall to provide a bone cutting guide surface to cutthrough the bone and optionally the teeth to create a reduced bone withteeth removed to receive implants. The anatomical guide has across-sectional thickness along the arch shaped structure to preventbuckling between the opposing interior wall and exterior wall. Thedental alignment guide system further has a surgical guide. The surgicalguide is made with a curved structure having a connection. The curvedstructure has a plurality of openings extending from an outer surfacetoward a reduced bone surface of the alveolar process. The openings areconfigured to receive implants or drills for guiding the drills andimplants through the surgical guide as planned. The connection extendsfrom the curved structure to an end. The connection is sized to bereceived and complimentarily fit into a connection aperture of the latchon the anatomical guide and thereafter supported on the pins. Theanatomical guide and the surgical guide when connected together form anassembly. The connection of the surgical guide is dimensionally the sameas the connection of the tooth guide to fit the connection aperture ofthe anatomical guide. The surgical guide has an exposed outer surfacewith a plurality of implant openings each implant opening being a guidetube. Each guide tube is positioned in one of the plurality of implantopenings to direct a placement of a drill and an implant into thereduced bone. The surgical guide further has an analog model replicatingthe patient's reduced bone with implant placements. The analog model hasa pair of attachment openings configured to receive an articulationpiece. The dental alignment guide system further has an articulationpiece. The articulation piece has a pair of attachment posts forattachment into the pair of attachment openings on the surgical guide.The articulation piece replicates the patient's teeth and bone thatexisted prior to a bone reduction to provide for alignment andarticulation. The dental alignment guide system further has a prostheticseat with openings aligned with the implant openings, the prostheticseat being positioned on the reduced bone with identifying markers forabutment pieces to be attached to the implants in the reduced bonebetween the reduced bone and the artificial teeth. The dental alignmentguide system further has an anatomical model of the patient's teeth andexposed alveolar process with soft tissue removed to replicate thepatient's teeth and mandible or maxilla prior to any teeth extraction orbone reduction. The anatomical model is a three-dimensional model madeby combining laser scanning of the patient's teeth with a CT image ofthe patient's anatomy and 3D printing. The dental alignment guide systemfurther has a plurality of implants. The implants are configured to passthrough the guide tubes of the surgical guide. The implants are driveninto the reduced bone while being guided by the guide tube securelyfixed to the bone at a desired angle, depth and rotation. The rotationis controlled by aligning markers on the implant driver to markers onthe surgical guide at a depth stop. The system further has abutments forattachment to the implants. Each abutment has one or more alignmentflats or slots and the prosthetic seat is marked to indicate analignment location for the flats or slots to control rotation to adesired angle. Each abutment has internal threads. Each abutment has anexposed end configured to receive and temporarily hold a cylinder, eachcylinder being pre-cut to a desired length. The dental alignment guidesystem further has prosthetic artificial teeth. The artificial teethhave a connection configured to align with the connection aperture ofthe anatomical guide to form an assembly. The prosthetic artificialteeth have a plurality of holes configured to align with the cylindersattached to the abutments and to receive the cylinders into the holes atthe desired length so the cylinder end is at or below the surface of theteeth when the artificial teeth are attached to the anatomical guide.The dental alignment guide system further has a plurality of straws. Astraw is inserted into an open end of the cylinder to occlude theopening to the screw access to prevent occlusion of the access when alight or self-curing material is applied to the holes of the artificialteeth to bond and secure the cylinders to the artificial teeth. Theartificial teeth are removed from the anatomical guide with thecylinders fixed to the artificial teeth. The connection is removed andthe artificial teeth are polished and prepared for placement into thepatient. The anatomical guide is unfastened from the bone and the softtissue flap sutured prior to attaching the artificial teeth. A pluralityof screws are configured to pass through the cylinders and thread intothe abutments thereby securing the artificial teeth to the reduced bone.

in one embodiment, the anatomical guide has a nasal vertical mountportion integrally formed or otherwise affixed to an opposing outersurface relative to the flat outer surface. The nasal vertical mountportion extends from the anatomical guide to buttress against cheekbones. The portion has nasal clips configured to assist in verticallypositioning the anatomical guide interior surface against the exposedbone of the maxilla. In the preferred embodiment, each nasal clip has anaperture.

Definitions

The alveolar process (alveolar bone) is the thickened ridge of bone thatcontains the tooth sockets (dental alveoli) on bones that hold teeth. Inhumans, the tooth-bearing bones are the maxillae and the mandible.

Anterior -The direction towards the front of the head or the lips, asopposed to posterior, which refers to the directions towards the back ofan individual's head. The term anterior teeth refers to incisors andcanines, as opposed to premolars and molars, which are posterior teeth.

Apical—The direction towards the root tip(s) or apex(es) of a tooth (theapices), as opposed to coronal, which refers to the direction towardsthe crown. It may also refer to something relating to the roots, such asapical support. When referring to direction in relation to entities onor of the crown, this term can be synonymous with both cervical andgingival.

Axial—A plane parallel to the surface of a tooth. For example, if adrill bur would be inserted into a tooth from any side (proximal,vestibular, oral), the depth of the hole is defined from the axial wallof the hole (from the long axis walls (vertical surfaces bounding thetooth)).

Buccal—The side of a tooth that is adjacent to (or the directiontowards) the inside of the cheek, as opposed to lingual or palatal (bothoral), which refer to the side of a tooth adjacent to (or the directiontowards) the tongue or palate, respectively, the oral cavity. Althoughtechnically referring only to posterior teeth (where the cheeks arepresent instead of lips, use of this term has incorrectly extended toall teeth, anterior and posterior), this term has inaccurately beenemployed to describe the vestibular surface of (or directions inrelation to) anterior teeth as well.

Cervical—Means neck in Latin (as in cervical vertebrae), and refers tothe narrowing of the contours of the tooth surface at or near the CEJ,where the crown meets the root. When referring to direction in relationto entities on or of the crown, it is nearly synonymous with both apicaland gingival.

Coronal—The direction towards the crown of a tooth, as opposed toapical, which refers to the direction towards the tip(s) of the root(s)or apex(es). It may also refer to something relating to the crown, suchas coronal forces.

Distal—The direction towards the gingiva beyond the tooth furthest fromthe anterior midline (the ‘most posterior tooth’ or last tooth) in eachquadrant of a dental arch, as opposed to mesial, which refers to thedirection towards the anterior midline. Each tooth can be described ashaving a distal surface and, for posterior teeth, a distobuccal (DB) anda distolingual (DL) corner or cusp.

Facial—The side of a tooth that is adjacent to (or the directiontowards) the inside of the lips, as opposed to lingual or palatal (bothoral), which refer to the side of a tooth adjacent to (or the directiontowards) the tongue or palate, respectively, the oral cavity. However,this term has been incorrectly used as an umbrella term for both theterm buccal and labial, being also applied to the side of a tooth thatis adjacent to (or the direction towards) the inside of the cheek(instead of the more accurate term, vestibular).

Gingival—The direction towards the gingiva (gums), synonymous withcervical and similar to apical. However, locations on teeth already moreapical to the interface of the crown and root, referred to as the CEJ,tend not to be described using this term, as it would lead to confusion,as the exact definition is ambiguous. Additionally, this term would notbe used when referring to a tooth ex vivo.

Incisal—The direction towards the biting edge of anterior teeth orsomething relating to this edge, such as the terms incisal guidance orincisal edge. This is the sister term to occlusal, which related to theanalogous location on posterior teeth.

Inferior—The direction towards the feet of a human's body, as opposed tosuperior, which refers to the direction towards the head. However, useof these terms should enjoy only limited usage when discussing featuresof a tooth, as, for example, something more inferior on a mandibulartooth will be situated more superior on a maxillary tooth, as theyexhibit an inverted relationship. It is for this reason that the termscoronal and apical are substituted.

Interproximal—An adjective meaning between teeth. For example,interproximal teeth refers to the space between adjacent teeth.

Labial—The side of a tooth that is adjacent to (or the directiontowards) the inside of the lip (labium), as opposed to lingual orpalatal (both oral), which refer to the side of a tooth adjacent to (orthe direction towards) the tongue or palate, respectively, the oralcavity. Although technically referring only to anterior teeth (where thelips (labia) are present instead of cheeks), use of the term buccal hasinaccurately extended to all teeth, anterior and posterior (instead ofvestibular, the umbrella term).

Lingual—The side of a tooth adjacent to (or the direction towards) thetongue (lingua, compare linguistics and language), as opposed to buccal,labial, or vestibular which refer to the side of a tooth adjacent to (orthe direction towards) the inside of the cheek or lips, respectively.Although this term is technically specific to the mandible, it enjoysextensive use in reference to the maxilla as well (see Palatal).

Mandibular Entities related to the mandible, or lower jaw.

Marginal—A number of different ‘margins’ that are involved in dentistry.The edge of tooth structure that is prepared to meet the edge of aprosthetic crown is called a margin, as is the aforementioned edge ofthe crown; an example of this usage would be “a poorly fitting crownmight exhibit marginal leakage.” The gingiva and bone that abut theteeth are referred to as ‘marginal’, as in marginal periodontitis. Thebulk of tooth structure on the occlusal surface at the point of contactof posterior teeth is referred to as the marginal ridge.

Maxillary Entities related to the maxilla, or upper jaw.

Mesial—The direction towards the anterior midline in a dental arch, asopposed to distal, which refers to the direction towards the gingivabeyond the tooth furthest from the anterior midline (the ‘most posteriortooth’ or last tooth) in each quadrant. Each tooth can be described ashaving a mesial surface and, for posterior teeth, a mesiobuccal (MB) anda mesiolingual (ML) corner or cusp.

Midline—Main article: Dental midline. Roughly, an imaginary verticalline dividing the left and right sides of the mouth at the teeth.

Occlusal—The direction towards the biting surface of posterior teeth orsomething relating to this surface, such as the terms occlusalinterference or occlusal surface. This is the sister term to incisal,which related to the analogous location on anterior teeth.

Oral—The side of a tooth adjacent to (or the direction towards) the oralcavity, as opposed to buccal, labial or vestibular, which refer to theside of a tooth adjacent to (or the direction towards) the inside of thecheek, lips or vestibule respectively. This term is an umbrella term forboth the term palatal and lingual. Alternatively, the term lingual hasbeen used as a blanket term instead although this specifically refersonly to the side of a tooth that is adjacent to (or the directiontowards) the tongue, technically specific to the mandible.Palatal—The side of a tooth adjacent to (or the direction towards) thepalate, as opposed to buccal, labial or vestibular which refer to theside of a tooth adjacent to (or the direction towards) the inside of thecheek, lips and vestibule of the mouth respectively. This term isstrictly used in the maxilla.Posterior—The direction towards the back of an individual's head, asopposed to anterior, which refers to the directions towards anindividual's lips. The term posterior teeth refers to premolars andmolars, as opposed to incisors and canines, which are anterior teeth.Proximal—The surfaces of teeth that normally lie adjacent to anothertooth. It is an umbrella term that includes both mesial and distal, suchas when referring to the proximal surfaces of teeth.

Dental quadrants—The dentition is divided into four quarters. The twodental arches form an oval, which is divided into quadrants: Upper rightquadrant: upper right first incisor to upper right wisdom tooth. Upperleft quadrant: upper left first incisor to upper left wisdom tooth.Lower right quadrant: lower right first incisor to lower right wisdomtooth. Lower left quadrant: lower left first incisor to lower leftwisdom tooth. Sextant—One of six groups of adjacent teeth, excluding thewisdom teeth. The front sextants go from canine to canine, and there aresextants on the right and left of these.

Superior—The direction towards the head of a human's body, as opposed toinferior, which refers to the direction towards the feet. However, useof these terms should enjoy only limited use when discussing features ofa tooth, as, for example, something more superior on a mandibular toothwill be situated more inferior on a maxillary tooth, as they exhibit aninverted relationship. It is for this reason that the terms coronal andapical are substituted.

Vestibular—The side of a tooth that is adjacent to (or the directiontowards) the inside of the cheeks and lips, as opposed to lingual orpalatal (both oral), which refer to the side of a tooth adjacent to (orthe direction towards) the tongue or palate, respectively, the oralcavity. This term is an umbrella term for both the term buccal andlabial. Alternatively, the term facial has been used as the umbrellaterm instead although this specifically refers only to the side of atooth that is adjacent to (or the direction towards) the inside of thelips, as opposed to lingual or palatal (both oral), and not the cheeks.

Zygoma implants (or Zygomatic implants) are different from conventionaldental implants in that they anchor in to the zygomatic bone (cheekbone) rather than the maxilla (upper jaw). They may be used whenmaxillary bone quality or quantity is inadequate for the placement ofregular dental implants.

BRIEF DESCRIPTION OF THE DRAWINGS

The patent or application file contains at least one drawing/photographexecuted in color. Copies of this patent or patent applicationpublication with color drawing(s) will be provided by the Office uponrequest and payment of the necessary fee.

The invention will be described by way of example and with reference tothe accompanying drawings in which:

FIG. 1A is a view of the various components of the dental alignmentsystem of the present invention.

FIG. 1B is a perspective view of the abutments and fasteners used tosecure an exemplary set of artificial teeth.

FIG. 1C is a view of exemplary abutments.

FIG. 1D is a view of various implant parts and abutments.

FIG. 1E is a perspective view of the various fasteners used with thesystem and the prosthetic seat.

FIG. 1 is a frontal perspective view of a tooth supported guide of thepresent invention. FIG. 2 is a frontal perspective view of theanatomical guide of the present invention.

FIG. 3 is a frontal perspective view of an anatomical model of anexemplary patient's teeth and bone with the soft gum tissue removed.

FIG. 4 is a frontal perspective view of the tooth supported guideinserted into the anatomical guide to form an assembly, the assembly, asillustrated, being placed on the anatomical model of FIG. 3.

FIG. 4A is a perspective view of the support pin of the latch.

FIG. 4B is a cross sectional view of the latch system of the presentinvention.

FIG. 5 is a perspective view of the surgical guide.

FIG. 6 is a frontal perspective view of the surgical guide shownattached to the anatomical guide for an assembly.

FIG. 7 is a frontal view of an articulation piece, the articulationpiece is a 3D model of the patient's existing teeth and bone that wasremoved having a pair of pegs configured to fit into the analog model.

FIG. 8 is a view of the articulation piece shown assembled to the analogmodel.

FIG. 9 is a view of artificial PMMA teeth with support bars forattachment to the anatomical guide.

FIG. 10 is a frontal view of the artificial teeth seated on theanatomical guide.

FIG. 11 is an analog model of the present invention.

FIG. 12 is a nasal vertical mount guide of the present invention.

FIG. 13 is a schematic diagram of the method of the present invention.

FIG. 14 is a frontal view of a patient being prepared for dental surgeryshowing the teeth and gums prior to flapping.

FIG. 15 is the frontal view of the patient of FIG. 14 showing the teethand exposed bone after the gum tissue has been flapped.

FIG. 16 is a view of the patient showing the surgeon placing a toothsupported guide and anatomical guide onto the patient's teeth andexposed bone.

FIG. 17 is a frontal view of the tooth mounted guide and the anatomicalguide assembly showing a tool being placed through a window opening toverify the tooth supported guide is properly resting on top of theteeth.

FIG. 18 shows the assembly fitted onto the teeth after the surgeon hasremoved two teeth that would have interfered with screw placement, asshown three screws are illustrated fastening the anatomical guide to thelabial side of the exposed bone and two alignment pins are also shownsecuring the tooth supported guide to the anatomical guide.

FIG. 19 is an enlarged view of FIG. 18.

FIG. 20 is a view of the anatomical guide securely fastened to thepatient's bone with the tooth mounted guide removed.

FIG. 21 shows the surgeon extracting the patient's teeth with theanatomical guide fastened to the exposed bone along the interior wall.

FIG. 22 is a view of the surgeon reducing the bone using the top surfaceof the anatomical guide to guide a reciprocating saw to reduce the boneto the level of the anatomical guide.

FIG. 23 is a view showing the bone after being reduced from a generallyfrontal perspective.

FIG. 24 is a view showing the bone after being reduced from a generallytop perspective.

FIG. 25 is a view of a surgical guide mounted onto the anatomical guideover the reduced bone.

FIG. 26 is a view of implant drivers positioned into the surgical guide.

FIG. 27 is an enlarged view of two of the drivers on a left side of thesurgical guide, the space between the surgical guide and the anatomicalguide providing visual access for the surgeon.

FIG. 28 is a view showing the anatomical guide with the surgical guideremoved.

FIG. 29 is a view of a prosthetic seat positioned over the implants, theprosthetic seat is an optional device used to seat the abutments.

FIG. 30 is a view of pre-cut to length cylinders placed onto theabutments driven and secured to the reduced bone with the anatomicalguide in place.

FIG. 31 is a view showing PMMA artificial teeth with support barsattached and pinned to the connection attachments of the anatomicalguide with the prosthetic seat being between the reduced bone and thebottom surface of the artificial teeth, the teeth having holesconfigured to receive the pre-cut cylinders which have short strawsplaced in each cylinder opening.

FIG. 32 is a view taken from FIG. 31 showing the cylinders being lootedin place using a light curing adhesive.

FIG. 33 is a top view of the artificial teeth after being removed fromthe anatomical guide showing the cylinders fixed in place.

FIG. 34 is a bottom view of the artificial teeth showing the enlargedbottom of the cylinders configured to fit onto the implants.

FIG. 35 is a tilted frontal view of the artificial teeth.

FIG. 36 is a view of the reduced bone with the abutments projectingslightly and the exposed bone with the anatomical guide removed prior tothe surgeon grafting and suturing the gum flap.

FIG. 37 is a view of the artificial teeth showing the support barsremoved and the PMMA artificial teeth polished prior to placement.

FIG. 38 is a view of the patient's mouth open and the artificial teethsecurely fastened to the implanted abutments with the gum tissuestitched in place.

FIG. 39 is a view of the patient's mouth closed partially to show thefit of the artificial teeth after surgery.

DETAILED DESCRIPTION OF THE INVENTION

With reference to the following drawings represented in FIGS. 1A-12, aplurality of devices that make up the dental alignment guide system 100of the present invention are shown. With reference to FIG. 13, adiametric schematic plan illustrates how the dental alignment guidesystem is used in preparing and implanting a dental implant into apatient. With reference to FIGS. 14-39, an exemplary procedure of adental implant being placed into a patient utilizing the dentalalignment guide system 100 of the present invention is illustratedshowing the techniques and methods used in utilizing the dentalalignment guide system of the present invention.

The present invention affords an opportunity to enable a surgeon toquickly accurately and very precisely implant artificial teeth into apatient with a minimum amount of time under sedation with theopportunity to provide adequate cooling of the underlying bone structureto insure there is no bone degradation during the procedure. Thesebenefits will be described in conjunction with the various devices thatare used in the alignment system. The system 100 shown in FIGS. 1A and1E, can be considered a kit composed of a variety of components, some ofthe components being manufactured using rapid printing or 3D printingtechnology and additive building using computer software that will mimicand accurately profile the devices to complimentarily match thepatient's existing teeth in many cases or exposed bone of either themandible or the maxilla providing a secure anatomical guide system toallow bone reduction to occur in a very precise manner so that whenimplants are placed to attach artificial teeth to the bone structure andsecured thereto, the implant will have a very refined alignment suchthat the implanted artificial teeth will fit precisely in the patientsmouth.

With reference to FIG. 1, a tooth supported guide 10 or also referred toas a tooth vertical mount is shown. The tooth supported guide 10 isillustrated has an arch shaped structure with an internal cavity 17 thatreplicates the patients existing teeth. On the outer surface of thecurved “U” shaped structure are a plurality of windows or holes 16 thatallow the tooth supported guide 10 to be checked and verified for properplacement when positioned over a patient's existing teeth. Asillustrated, the tooth supported guide 10 is for the lower teeth securedto the mandible or the alveolar process of the patient. Extendingoutward in a forward direction form the “U” shaped structure is aconnection 11, the connection 11 is at least one support bar 11 asshown, there are a plurality of support bars 11. Each support bar 11extends to an end, the curved structure has a first end and a secondend. In proximity to each end is one support bar 11. As shown in FIG. 1,the support bars 11 in proximity to the ends have a shape that has alower end that is of a polygonal cross section having three or moresides, as shown square or rectangular. Alternatively, a circularcross-section or any combination thereof can be used. Each of thesesupport bars 11 at the ends has a through hole 13, this through hole 13is for alignment purposes and most importantly for support. Interposedbetween the two support bars 11 in proximity to the first and second endis a middle support bar 18. The middle support bar 18 in the middlelocation has a circular or round cross-sectional peg or pin 14. Spanningbetween each support bar 11, 18 is a support structure 19 connectingeach support bar 11, 18 and providing additional rigidity between thesupport bars at a location between the top and the bottom of eachsupport bar 11, 18. As shown, each support bar has an enlarged section12 directly above the end. These enlarged sections 12 provide stops.

With reference to FIG. 2, an anatomical guide 20 is illustrated. Theanatomical guide 20 as shown is a curved arch with an interior wall 21and an exterior wall 21A. The distance between walls provides athickness, as shown the anatomical guide 20 typically has a thickness ofapproximately 6 mm. This is substantially thicker than most otherguides. Interestingly, the interior wall 21 is designed using a 3D scanof the patient to directly mimic the bone of the patient. The patient'steeth and bone having been previously scanned allows the software topredict the bone surface when the gum tissue has been flapped ordisplaced. As such the anatomical guide 20 will fit precisely againstthe bone in the absence of the gum tissue. The top surface 22 betweenthe interior wall 21 and the exterior wall 21A creates a flat surface 22that will facilitate the surgeon in making a bone reduction when theanatomical guide 20 is secured tightly to the patient's alveolarprocess. The anatomical guide 20 has at least one opening 23 forreceiving a fastener to secure the guide 20 to the exposed bone. Asillustrated, there are a plurality of fastener openings 23. The fasteneropenings 23 are provided to secure the anatomical guide 20 to thepatient's bone using threaded fasteners or screws. Additionally, atleast one connection aperture 24 is provided to receive a connectionfrom the tooth supported guide 10, as shown, there are a plurality ofapertures 24. One connection aperture 24 is near a first end and asecond connection aperture 24 is in proximity to a second end with amiddle connection aperture 28 that is of a round cross section showninterposed between the first two apertures. As previously discussed, thetooth supported guide 10 or vertical tooth mount can be assembledwherein the support bars 11, 18 are pushed onto and into the connectionapertures 24 of the anatomical guide 20. When this occurs, theconnection apertures 24 have holes 24A that align with the holes 13 atthe ends of the support bars 11 to receive the support pins 92 as shownin FIG. 4A and 4B to support the tooth supported guide 10. When theassembly of the tooth supported guide 10 and the anatomical guide 20 ismade, pins 92, shown in FIG. 1E, can be positioned in the support barholes 13 and connection aperture holes 24A securing the assembly.

With reference to FIG. 3, a model 70 of the patient's bone and existingteeth with the gum flap removed is made by a 3D image that exactlyreplicates this structure. This provides the surgeon with an opportunityto place the assembled tooth supported guide 10 and anatomical guide 20as an assembly over the replicated bone 4′ and teeth 2′ model 70 toinsure proper alignment and fit. As shown, the patient's bone and scanof teeth of the model 70 has a plurality of holes 71 that allow thesurgeon to fasten the anatomical guide 20 directly to the portionreplicating the exposed bone. This is the exact procedure that will bereplicated when doing a surgery on a patient's failing teeth. As shown,in the patient bone and laser scanned teeth model 70, there is a ridge72 between the teeth 2′ and the bone 4′ and it is important that theassembly of the tooth supported guide 10 and anatomical guide 20 areable to pass over the teeth 2 in such a way that the anatomical guide 20at the interior wall 21 is positioned below this ridge 72. In order toaccomplish that, the internal cavity 17 of the tooth supported guide 10is such that it can be tilted at a slight angle outward or proximally sothat as the surgeon is placing the assembly over the teeth 2, the toothsupported guide 10 will slide down and over the teeth 2 while projectingslightly outwardly. As this is occurring, the entire assembly will pivotwhile rotating down so that the interior wall 21 of the anatomical guide20 passes over this ridge 72 and lies directly under it, as illustratedin FIG. 4.

With reference to FIG. 4, the assembly of the tooth supported guide 10and the anatomical guide 20 is shown placed over the model 70 of apatient's bone 4′ and scan of the teeth 2′. When this occurs, theinterior wall 21 which exactly replicates the bone structure 4, will sitvery flush and precisely against the bone structure 4, the surgeon willthen look at the patient and determine whether or not the fastener holes23 are free of any obstructing tooth roots. If a tooth 2 is in the way,the surgeon will remove the entire assembly 10, 20 and extract any teeth2 that are interfering with any fasteners 90. Then the surgeon willplace the assembly back over the teeth 2 and fasten the screws orfasteners 90 in place. In addition, the holes 13, 24A provided foralignment will be filled with a pin 92, illustrated in FIG. 4A, andshown later in a discussion of an actual procedure. These alignment pins92 extend through the anatomical guide 20, through the hole 13 in thesupport bar 11 end and reenter a hole 24A on the interior wall 21 suchthat the tooth supported guide 10 is securely fastened to the anatomicalguide 20 prior to fastening the anatomical guide 20 to the bone 4. Theanatomical guide 20 can be provided with optional metal sleeves 23A thatwill be illustrated in later views on an existing patient. These sleeves23A, if used, provide a reinforcement of the fastening openings 23. Whena fastener 90 is inserted into the anatomical guide 20, it is preferablya threaded screw 90 that fits flush against the fastener opening 23.This allows for a tight fit with minimal obstruction in the patient'smouth. As noted, the arch shaped anatomical guide 20 only contacts thelabial side of the bone 4 in such a way that none of the anatomicalguide 20 is on the lingual or interior side of the patient's bone. Thisis important in that there is no need when using the system of thisinvention for any flapping any of the interior gum surface of thepatient. Only a small external flap on the labial side is needed withregard to utilizing this system 100.

Once the anatomical guide 20 is securely in place, the surgeon canremove the tooth supported guide 10, extract the existing teeth 2 andthen can take a reciprocating saw 200 and reduce the bone 4 such that itis flush with the anatomical guide 20, as shown in FIGS. 21 and 22. Thesurgeon will utilize the top surface 22 of the anatomical guide 20 toassist in establishing the distance and the amount of bone material tobe removed from the patient.

After the bone 4 is reduced, a surgical guide 40 can be provided, asshown in FIG. 5, that will mount directly into the connection apertureof the latch supported by the pin 92 and cantilevered over theanatomical guide 20 which has been fixed to the patient's bone 4. Thesurgical guide 40 has a plurality of openings 41 called drill guideopenings that assist the surgeon in establishing locations to which thebone 4 will be drilled to receive implants 95. In the present invention,multiunit abutments 94 shown in FIGS. 1B and 1C will be used tofacilitate preparing the patient's bone for receiving a prostheticartificial tooth assembly 60. The surgical guide 40 has a plurality ofsupport bars 42 identical to those of the tooth mounted guide 10. Thereis a first support bar 42 at a first end and a second support bar 42 ata second end has the similar polygonal cross-sectional shape with holes42A to secure the surgical guide 40 exactly in place on top of thereduced bone 4 and the anatomical guide 20. There is a middle supportbar 48 that fits into the middle aperture 28 of the anatomical guide 20.Once assembled, the surgical guide 40 and anatomical guide 20 form anassembly supported by pin and latch and cantilevered over implant sites,shown in FIG. 6, that is precisely and securely fastened to the bone 4.Again, as an assembly, all of the connections are provided by latchesand pins in the anatomical guide 20. The surgical guide 40 has aplurality of drill guide holes 41 that enable the surgeon to preciselylocate the placement of multiunit abutments 94 for later securingartificial teeth 60. As previously discussed, the surgical guide 40 canhave one or at least one connection, but is shown with a plurality.

With reference to FIG. 7, the dental alignment system further has anarticulation piece 75. The articulation piece 75 has a pair of pegs 76that fit directly into openings 79 in an analog model 78. As shown thearticulation piece 75 has the patient's existing teeth 2 and the bone 4that was removed during the bone reduction process replicated. Thearticulation piece 75 is used to ensure for the surgeon that the boneafter being reduced is properly prepared so that the alignment of thejaws is such that the existing teeth 2 can be replicated, even thoughthey have been removed and the bone 4 has been reduced. This is shown inFIG. 8 inserted into the analog model 78, mimicking what would happen ina patient.

With reference to FIG. 9, prosthetic artificial teeth 60 are shown thatwill be replacing the existing teeth 2. As shown, the artificial teeth60 have a plurality of support bars 61, 68, again the support bars 61 ata first end and a second end have a cross sectional polygonal shape tofit into and be pinned to the anatomical guide 20 and a middle round peg34. The artificial teeth support bars 61, 68 do not have an additionalprojection or stop like the tooth mounted guide 10, but fit directlyinto the apertures 24 of the anatomical guide 20 as shown in FIG. 10. Asnoted, the connection 11, 43, 61 into the connection aperture 24 of theanatomical guide 20 could be as few as one, but is shown with aplurality.

With reference to FIG. 11, an analog model 78 is provided showing thereduced bone and all the holes 79 used for attachment and positioning ofthe artificial teeth 60. The analog model 78 exactly replicates thepatient's existing bone 4 and the reduction that has occurred. Holesrepresent where implants will be for abutment placement and titaniumcylinder placement and prosthetic teeth.

In the first embodiment illustrated, the system 100 was shown being usedon the mandible or lower teeth. The dental alignment system 100 isequally suited to be used on the upper teeth using the anatomical guide20 with or without a tooth supported guide 10 or optionally using theanatomical guide 20 with a nasal vertical mount 85 in such a fashionthat support is provided by the nasal bone structure. The nasal verticalmount 85 has a similar “U” shaped cross section and can be fitted on thefront facial bone and nasal floor. The combination of the toothsupported mount 10 with the anatomical guide 20, or the anatomical 20with or without the nasal vertical mount 85 allows the surgeon toaccurately do both arches, in other words he can do a procedure on thelower teeth and sequentially can do the upper teeth while the patient isunder sedation. This is made possible in part due the rapid and precisenature that allows the surgeon to operate quickly with sufficient amountof time to achieve both procedures at one time if so desired.Additionally, as noted and as will be seen, during the procedure, thesurgeon can irrigate and flush and drain blood and other tissue duringthe procedure due to the windows in the different components and spacingbetween the components that allow the surgeon to visually see the drillholes as he proceeds. This will be described later in the discussion ofthe device. To summarize, for the lower arch, a surgeon can seat theanatomical guide 20 on facial bone only or use the tooth supported guide10 and the anatomical guide 20 combined. There are three options ofsupport for the upper arch, the first two are identical to the lowerarch, one; tooth and facial anatomy, two; facial anatomy; or the third,specific to the upper arch, facial anatomy and nasal bone structure. Inall cases, the anatomical guide 20 is used. Due to the accuracy of theinterior wall 21 of the anatomical guide 20, to match the labial bone,providing an intimate matching fit to this facial bone, a skilled orexperienced surgeon can use the anatomical guide 20 only, proceeding andsecuring the anatomical guide 20 to this bone. this feature andcapability make the anatomical guide 20 unique compared to all otherprior art guides. The Surgical Guide 40 is rigidly supported by thelatches or connections on the support bars 42, 48 at the connectionapertures 24 of the anatomical guide 20. There is a space between theSurgical Guide 40 and the Anatomical Guide 20. This creates a gappreventing the surgical guide 40 from sitting on the top surface andcutting surface 22 of the anatomical guide 20. This gap keeps damagefrom the doctor cutting the anatomical guide 20 accidentally frompreventing the seating of the surgical guide 40. The Surgical Guide 40is cantilevered over the Anatomical guide 20 and the bone. The toothsupported guide 10 will also rest on the latches or connections on thesupport bars 11, 18 at the connection apertures 24 and cantilever overthe anatomical guide 20. Similarly, the prosthetic teeth 60 are held ina planned position over the abutments 94. As used herein, the latches orconnections are referred to as “Diamond Latches” by the inventor. Theselatches form the connections of the various parts to the anatomicalguide 20. These connections represent each of support bars 11, 18, 42,48, 61, 68 of the various devices to be attached to the anatomical guide20 that fits at an end into the connection apertures 24 of theanatomical guide 20. The end has a hole that is pinned to the anatomicalguide 20 at each support bar 11, 42, 61. All the support bars have anenlarged section that abuts against a top surface at the connectionaperture 24 to form the rigid connections.

A rough schematic is provided in FIG. 13 indicating the general implantprocedure. In this procedure, it must be understood that the componentsthat have been pre-fabricated using a 3D scanned laser image to mimicsurfaces of the various components needed to fit precisely in thepatient's mouth. When all the components have been made, the patient canbe taken into the operating room. The first step will be to create aflap buccal or labial of the patient. In this case the flap is a portionof the soft gum tissue that is removed from the bone 4 and folded backso the anatomical guide 20 will fit tightly against the bone 4. Thesecond step is the seating of the anatomical guide 20 with or withoutusing the tooth mounted guide 10 or vertical mount that will sit on theteeth 2 and bone 4 anatomy of the patient. In the next step, theanatomical guide 20 will be screwed or fastened to the patient. Thefourth step requires the vertical mount 10 to be removed. The fifth steprequires the teeth 2 to be extracted and the bone reduced or reduce bonewith the teeth in place. The sixth step requires the surgical guide 40to be connected to the anatomical guide 20. The seventh step requiresthe implants 95 to be placed, the implants 95 as will be seen later aremultiunit anchors that provide anchoring locations for the artificialteeth 60. The anchoring locations are optionally multiunit abutments 94.Step 8 is the optional abutments 94 placed and titanium cylinders. Stepnine is the artificial teeth with latches are connected to theanatomical guide and in step ten, titanium cylinders 98 are looted inthe artificial teeth 60, the cylinders 98 are fixed to the artificialteeth 60. The artificial teeth 60 can then have the connection orsupport bars removed and be prepared for implantation.

Prior to a patient going into surgery, a complete 3-dimensional digitalimage, CT scan or laser scanning of the patient's mouth with theexisting teeth in place is made. The CT scan and the digital images ofthe teeth are imported into a software to plan implant placement. Thisplan will be used to create the reduction, implant guide, analog modeland all other pieces. From this scan, the various guides are made,including a complete fabrication of the artificial teeth that will bereplacing the patient's failing teeth.

The various components of the dental alignment guide system 100including those replicating the patient's existing teeth called thearticulation piece 75 and the analog model 78 as well as all the otherguides can be made using a pre-fabricated 3-D printing that preciselyand accurately matches the patient so a proper fit of the artificialteeth 60 can be achieved with a minimal amount of time.

With reference to FIGS. 14-39, an exemplary procedure is shown whereinthe dental alignment system 100 and its associated components areemployed. As shown in FIG. 14, the patient's front teeth 2 with the softgum tissue 5 still intact is shown. In FIG. 15, the same front teeth 2with the soft tissue 5 flapped is illustrated. As shown, the soft tissue5 is only removed on the labial side of the patient's front teeth 2,between the lips and the mandible.

With reference to FIG. 16, the anatomical guide 20 and the teeth mountedguide 10 are shown as an assembly placed over the patient's existingteeth 2. As illustrated, the tooth supported guide 10 rests on top ofthe teeth 2 as evidenced by the probe 210 that is passed through thewindow 16 to verify that the tooth supported guide 10 is positionedfully resting on the top of the teeth 2. At this point in time, theanatomical guide 20 is shown not affixed to the bone, however, it isattached securely but not yet pinned to the three support bars 11, 18 asshown in FIG. 17. The support bars 11 in proximity to the first end andsecond end have a polygonal shape as shown, shaped rectangular or squareand fits into a connection aperture 24 on the anatomical guide 20. Holes13 provided in the tooth supported guide 10 at the ends of the supportbars 11 in proximity to the ends of the anatomical guide 20 align withholes 24A in the connection apertures 24. The holes 24A in theconnection apertures 24 and the holes 13 in the tooth supported guide 10are aligned and can be pinned together to complete the assembly. Pins 92are not shown in this view of FIG. 17, but are shown in FIGS. 18 and 19.These pins 92 lock and support via a latched assembly of the two parts.As shown in FIGS. 18 and 19, the anatomical guide 20 has a plurality, asshown 3 fastener holes 23, for connection to the bone 4 of the patient.These fastener holes 23 can optionally have a metal sleeve 23A orbushing, best shown in FIG. 17, to provide additional support andstrength to the anatomical guide 20 when the fasteners 90 are insertedas shown in FIG. 20.

With reference to the FIG. 17, when the bone guide 20 and tooth mountedguide 10 assembly are positioned in the patient's mouth, it may bepossible that the screw hole openings will align directly into a tooth 2or a root of a tooth and as a result, the surgeon may desire to extractthose teeth that interfere with the attachment of the bone screw 90. Asshown in FIGS. 18 and 19, two teeth have been removed in this example toallow the screws 90 to be attached without permanently leaving remnantsof the roots of the tooth. As shown, pins 92 are placed in the alignmentholes 24A at this point in time. These pins 92 secure the toothsupported guide 10 directly to the anatomical guide 20. Screws are thenplaced into the openings and the anatomical guide 20 is drawn tightlyand firmly against the exposed bone 4. This is as shown in FIGS. 16, 17,18, and 19.

Once the anatomical guide 20 is firmly attached to and fastened to thebone 4, the tooth supported guide 10 can be removed from the assembly.As illustrated in FIG. 20, once the tooth supported guide 10 is removed,the teeth are extracted and the bone is reduced, or optionally the bonecan be removed with the teeth. The surgeon can then reduce the bone 4down to the level of the bone guide surface 22 using a cutting tooloptionally a reciprocating saw 200. The outer top surface 22 of theanatomical guide 20 is used to help guide the reciprocating saw 200 tomake the necessary cuts as illustrated in FIG. 22. When fully reduced,the bone 4 is flush with the surface 22 of the anatomical guide 20 asillustrated in FIGS. 23 and 24.

With reference to FIG. 25, it is now possible to place the surgicalguide 40 support bars into the connection apertures of the latches andinserting pins 92 to support the surgical guide cantilevered over theanatomical guide 20. The surgical guide 40 has alignment tubes in theform of openings for placement and guiding a drill and positioningimplants. As shown in FIG. 26, the implant drivers are illustrated. Asshown the implant drivers 220 are driving the implant 95 into thereduced bone 4. In doing so, the implant drivers 220 while being rotatedare being controlled in depth, angulation and rotation. As shown in FIG.28, once the surgical guide 40 is removed the implants 95 are shownimplanted into the reduced bone 4 at proper depth and angulation. Oncethe implants 95 are positioned, a prosthetic seat 80 can be placed overthe implants 95 to place the abutments 94 to attach to the implants 95,as shown in FIG. 29.

As shown in FIG. 30, cylinders 98 are placed on the end of the multiunitabutments 94. These cylinders 98 have been cut to a predetermined lengthto match the prosthetic artificial teeth 60 that will be inserted later.These temporary cylinders 98 are substantially longer than are requiredfor the actual implant and, therefore, by knowing the precise depth andlength of the artificial teeth, the cylinders can be cut precisely to alength and marked where they go into the openings of the artificialteeth 60 pre-cut. This saves a tremendous amount of time in that thecylinders 98 are now pre-cut to the proper length prior to beinginserted onto the abutments 94.

As shown in FIG. 29, the prosthetic seat 80 is shown, the prostheticseat 80 is generally an elastomeric piece that can be produced in thelab, it replicates or simulates the gum tissue that will grow back andit will sit between the reduced bone 4 and the artificial teeth 60. Theprosthetic seat 80 is shown in FIGS. 31 and 32. The artificial teeth 60are placed over the cylinders 98 into position, the artificial teeth 60have support bars 61, 68 similar to those of the tooth supported guide10 and the surgical guide 40. These support bars 61, 68 have ends thatcomplimentarily fit into the anatomical guide 20 as previouslydiscussed. As shown, pins 92 are positioned through the holes 24A in theattachment connections 24 and through artificial teeth through thesupport bar holes 63 at each proximal end. The middle support bar 68 isa round pin 64 that fits into the anatomical guide 20 as previouslydiscussed. When the artificial teeth 60 are placed into position, smallremovable straws 99 are placed in each cylinder 98 these are put inplace prior to applying a light curing adhesive around each cylinder 98.The cured adhesive 97, shown in FIG. 34, is provided to securely fastenthe cylinders 98, shown in FIG. 30, directly to the artificial teeth 60.Once cured the surgeon can then remove the artificial teeth 60 and thecylinders 98 will be permanently attached to the artificial teeth 60shown in FIG. 33 in a top view and FIG. 34 in a bottom view.

The artificial teeth as shown in FIG. 35 have the support bars stillpositioned on the artificial teeth 60. At this point in time, thesurgeon can remove the one or more fasteners 90 and the anatomical guide20 leaving only the multiunit abutments 94 in the patient's mouth, asshown in FIG. 36. Then the surgeon can suture up the patient's gums 5and prepare the patient to receive the artificial teeth 60. During thistime, technicians can prepare the artificial teeth 60 for implantationby removing the support bars 61, 68 and polishing the teeth so they willhave a proper look and have the support bars completely removed as shownin FIG. 37. Once this is accomplished, the artificial teeth 60 arepositioned into the patients mouth and screws 91 threadingly engage themultiunit abutments 94 through the cylinder 98 to tighten the artificialteeth 60 firmly against the implanted abutments 94, hidden in FIG. 38,but shown in FIG. 1B. The finished artificial teeth 60 will appear asshown in FIG. 39.

Variations in the present invention are possible in light of thedescription of it provided herein. While certain representativeembodiments and details have been shown for the purpose of illustratingthe subject invention, it will be apparent to those skilled in this artthat various changes and modifications can be made therein withoutdeparting from the scope of the subject invention. It is, therefore, tobe understood that changes can be made in the particular embodimentsdescribed, which will be within the full intended scope of the inventionas defined by the following appended claims.

What is claimed is:
 1. A dental alignment guide system for dentalimplant placement comprises: an anatomical guide having an arch shapedstructure having a first end and a second end, the arch shaped structurehaving a curved exterior wall and a curved interior wall extendingbetween the ends, the interior wall formed to abut against and besecured to a portion of a labial and/or buccal side of a patient'sexposed bone of the alveolar process with soft gum tissue removed ordisplaced by flapping, the curved exterior wall having at least onefastener openings extending through the arch shaped structure, eachfastener opening configured to receive a fastener to secure theanatomical guide to the exposed bone of either the mandible or themaxilla; a plurality of fasteners, the plurality of fasteners arethreaded screws to fasten the anatomical guide to the exposed bone, eachthreaded screw passing through one of the plurality of fastener openingsof the anatomical guide; a surgical guide, the surgical guide with acurved structure having a connection; the curved structure having aplurality of openings extending from an outer surface toward a reducedbone surface of the alveolar process, the openings configured to receiveimplants or screws for seating the surgical guide, the connectionextending from the curved structure to an end, each end of theconnection being sized to be received and complimentarily fit into aconnection aperture on the anatomical guide; and wherein the anatomicalguide and the surgical guide when connected together form an assembly.2. The dental alignment guide system of claim 1, wherein the connectionof the surgical guide is dimensionally the same as the connection of thetooth guide to fit the connection aperture of the anatomical guide. 3.The dental alignment guide system of claim 1, wherein the surgical guidehas an exposed outer surface with a plurality of implant openings eachimplant opening being a guide tube, each guide tube being positioned inone of the plurality of implant openings to direct a placement of adrill and an implant into the reduced bone.
 4. The dental alignmentguide system of claim 1 further comprises: an analog model replicatingthe patient's reduced bone with implant placements, the analog model hasa pair of attachment openings configured to receive an articulationpiece.
 5. The dental alignment guide system of claim 4 furthercomprises: an articulation piece, the articulation piece has a pair ofattachment posts for attachment into the pair of attachment openings onthe analog model; and wherein the articulation piece replicates thepatient's teeth and bone that existed prior to a bone reduction toprovide for alignment and articulation.
 6. The dental alignment guidesystem of claim 5 further comprises: a prosthetic seat with openingsaligned with the implant openings, the prosthetic seat being positionedon the reduced bone with identifying markers for abutment pieces to beattached to the implants in the reduced bone between the reduced boneand the artificial teeth.
 7. The dental alignment guide system of claim1 further comprises: an anatomical model of the patient's teeth andexposed alveolar process with soft tissue removed to replicate thepatient's teeth and mandible or maxilla prior to any teeth extraction orbone reduction; wherein the anatomical model is a three-dimensionalmodel made by combining laser scanning of the patient's teeth with a CTimage of the patient's anatomy and 3D printing.
 8. The dental alignmentguide system of claim 5, further comprises: a plurality of implants, theimplants configured to pass through the guide tubes of the surgicalguide.
 9. The dental alignment guide system of claim 8, wherein theimplants are driven into the reduced bone while being guided by theguide tube securely fixed to the bone at a desired angle, depth androtation, rotation being controlled by aligning markers on the implantdriver to markers on the surgical guide at a depth stop.
 10. The dentalalignment guide system of claim 9, further comprises: abutments forattachment to the implants, wherein each abutment has one or morealignment flats or slots and the prosthetic seat is marked to indicatean alignment location for the flats or slots to control rotation to adesired angle; and wherein each abutment has internal threads andwherein each abutment has an exposed end configured to receive andtemporarily hold a cylinder, each cylinder being pre-cut to a desiredlength.
 11. The dental alignment guide system of claim 10, furthercomprises: a prosthetic artificial teeth, the artificial teeth have aconnection configured to align with the connection aperture of theanatomical guide to form an assembly; and wherein the prostheticartificial teeth have a plurality of holes configured to align with thecylinders and to receive the cylinders attached to the abutments intothe holes at the desired length so the cylinder end is at or below thesurface of the teeth when the artificial teeth are attached to theanatomical guide.
 12. The dental alignment guide system of claim 11,further comprises: a plurality of straws, a straw being inserted into anopen end of the cylinder to occlude the opening to the screw access;wherein a curing material is applied to the holes of the artificialteeth to bond and secure the cylinders to the artificial teeth.
 13. Thedental alignment guide system of claim 12, wherein the artificial teethare removed from the anatomical guide with the cylinders fixed to theartificial teeth.
 14. The dental alignment guide system of claim 13,wherein the connection is removed and the artificial teeth polished andprepared for placement into the patient.
 15. The dental alignment guidesystem of claim 14, wherein the anatomical guide is unfastened from thebone and the soft tissue flap sutured prior to attaching the artificialteeth.
 16. The dental alignment guide system of claim 15, furthercomprises: a plurality of screws configured to pass through thecylinders and thread into the abutments thereby securing the artificialteeth to the reduced bone.
 17. The dental alignment guide system ofclaim 1, wherein the anatomical guide has a flat outer surface extendingbetween the curved interior wall and the curved exterior wall to providea bone cutting guide surface to create a reduced bone with teeth removedto receive implants, and wherein the anatomical guide has a nasalvertical mount portion integrally formed or otherwise affixed to anopposing outer surface relative to the flat outer surface.
 18. Thedental alignment guide system of claim 17, wherein the nasal verticalmount portion extending from the anatomical guide to buttress againstcheek bones, the portion having nasal clips configured to assist invertically positioning the anatomical guide interior surface against theexposed bone of the maxilla, wherein each nasal clip has an aperture,wherein the surgical guide is rigidly supported by the connections onthe support bars and cantilevered over the anatomical guide forming aspace between the surgical guide and the anatomical guide creating agap, preventing the surgical guide from sitting on the top cuttingsurface of the anatomical guide while cantilevering over the bone. 19.The dental alignment guide system of claim 1 further comprises: a toothsupported guide with a “U” shaped curved structure configured tovertically fit onto a patient's existing teeth and a connectionextending from the “U” shaped curved structure to an end, the connectionbeing sized to be received and complimentarily fit into a connectionaperture on the anatomical guide; wherein the anatomical guide and thetooth supported guide when connected together form an assembly; whereinthe assembly of anatomical guide and the tooth supported guide are toothsupported vertically to align the interior wall of the anatomical guideto abut against the exposed bone prior to securing the anatomical guidewith fasteners to the exposed bone; and wherein the tooth supportedguide is removably attached to the anatomical guide as the assembly, andthe anatomical guide after being fastened to the exposed bone can havethe tooth supported guide removed from the assembly.
 20. The dentalalignment guide system of claim 1 wherein the anatomical guide has aflat outer surface extending between the curved interior wall and thecurved exterior wall to provide a bone cutting guide surface to create areduced bone with teeth removed to receive implants, wherein theanatomical guide has a cross-sectional thickness along the arch shapedstructure to prevent buckling between the opposing interior wall andexterior wall.